import argparse import os, glob import cv2 import librosa import numpy as np import soundfile as sf import torch import time from tqdm import tqdm from lib import dataset from lib import spec_utils from lib.model_param_init import ModelParameters class VocalRemover(object): def __init__(self, model, device, window_size): self.model = model self.offset = model.offset self.device = device self.window_size = window_size def _execute(self, X_mag_pad, roi_size, n_window, aggressiveness): self.model.eval() with torch.no_grad(): preds = [] for i in tqdm(range(n_window)): start = i * roi_size X_mag_window = X_mag_pad[None, :, :, start:start + self.window_size] X_mag_window = torch.from_numpy(X_mag_window).to(self.device) pred = self.model.predict(X_mag_window, aggressiveness) pred = pred.detach().cpu().numpy() preds.append(pred[0]) pred = np.concatenate(preds, axis=2) return pred def preprocess(self, X_spec): X_mag = np.abs(X_spec) X_phase = np.angle(X_spec) return X_mag, X_phase def inference(self, X_spec, aggressiveness): X_mag, X_phase = self.preprocess(X_spec) coef = X_mag.max() X_mag_pre = X_mag / coef n_frame = X_mag_pre.shape[2] pad_l, pad_r, roi_size = dataset.make_padding(n_frame, self.window_size, self.offset) n_window = int(np.ceil(n_frame / roi_size)) X_mag_pad = np.pad(X_mag_pre, ((0, 0), (0, 0), (pad_l, pad_r)), mode='constant') pred = self._execute(X_mag_pad, roi_size, n_window, aggressiveness) pred = pred[:, :, :n_frame] return pred * coef, X_mag, np.exp(1.j * X_phase) def inference_tta(self, X_spec, aggressiveness): X_mag, X_phase = self.preprocess(X_spec) coef = X_mag.max() X_mag_pre = X_mag / coef n_frame = X_mag_pre.shape[2] pad_l, pad_r, roi_size = dataset.make_padding(n_frame, self.window_size, self.offset) n_window = int(np.ceil(n_frame / roi_size)) X_mag_pad = np.pad(X_mag_pre, ((0, 0), (0, 0), (pad_l, pad_r)), mode='constant') pred = self._execute(X_mag_pad, roi_size, n_window, aggressiveness) pred = pred[:, :, :n_frame] pad_l += roi_size // 2 pad_r += roi_size // 2 n_window += 1 X_mag_pad = np.pad(X_mag_pre, ((0, 0), (0, 0), (pad_l, pad_r)), mode='constant') pred_tta = self._execute(X_mag_pad, roi_size, n_window, aggressiveness) pred_tta = pred_tta[:, :, roi_size // 2:] pred_tta = pred_tta[:, :, :n_frame] return (pred + pred_tta) * 0.5 * coef, X_mag, np.exp(1.j * X_phase) def main(): p = argparse.ArgumentParser() p.add_argument('--gpu', '-g', type=int, default=-1) p.add_argument('--pretrained_modelA', '-a', type=str, default='models/MGM-v5-4Band-44100-BETA1.pth') ##DON'T CHNGE p.add_argument('--pretrained_modelB', '-B', type=str, default='models/MGM-v5-4Band-44100-BETA2.pth') ##DON'T CHNGE p.add_argument('--pretrained_modelC', '-C', type=str, default='models/HighPrecison_4band_1.pth') ##DON'T CHNGE p.add_argument('--pretrained_modelD', '-Da', type=str, default='models/HighPrecison_4band_2.pth') ##DON'T CHNGE p.add_argument('--pretrained_modelE', '-E', type=str, default='models/NewLayer_4band_1.pth') ##DON'T CHNGE p.add_argument('--pretrained_modelF', '-F', type=str, default='models/NewLayer_4band_2.pth') ##DON'T CHNGE p.add_argument('--pretrained_modelG', '-G', type=str, default='models/NewLayer_4band_3.pth') ##DON'T CHNGE p.add_argument('--deepextraction', '-D', action='store_true') p.add_argument('--saveindivsep', '-s', action='store_true') p.add_argument('--input', '-i', required=True) p.add_argument('--nn_architecture', '-n', type=str, default='default') ##DON'T CHNGE p.add_argument('--nn_architectureA', '-aB', type=str, default='123821KB') ##DON'T CHNGE p.add_argument('--nn_architectureB', '-bA', type=str, default='129605KB') ##DON'T CHNGE p.add_argument('--model_params', '-m', type=str, default='modelparams/4band_44100.json') ##DON'T CHNGE p.add_argument('--window_size', '-w', type=int, default=512) p.add_argument('--output_image', '-I', action='store_true') p.add_argument('--postprocess', '-p', action='store_true') p.add_argument('--tta', '-t', action='store_true') p.add_argument('--high_end_process', '-H', type=str, choices=['none', 'bypass', 'correlation'], default='none') p.add_argument('--aggressiveness', '-A', type=float, default=0.09) args = p.parse_args() ####################################################-INERATION1-#################################################### if args.nn_architecture == 'default': from lib import nets dir = 'ensembled/temp' for file in os.scandir(dir): os.remove(file.path) #if '' == args.model_params: # mp = ModelParameters(args.pretrained_model) #else: mp = ModelParameters(args.model_params) start_time = time.time() print('loading MGM-v5-4Band-44100-BETA1...', end=' ') device = torch.device('cpu') model = nets.CascadedASPPNet(mp.param['bins'] * 2) model.load_state_dict(torch.load(args.pretrained_modelA, map_location=device)) if torch.cuda.is_available() and args.gpu >= 0: device = torch.device('cuda:{}'.format(args.gpu)) model.to(device) print('done') print('loading & stft of wave source...', end=' ') X_wave, y_wave, X_spec_s, y_spec_s = {}, {}, {}, {} basename = os.path.splitext(os.path.basename(args.input))[0] bands_n = len(mp.param['band']) for d in range(bands_n, 0, -1): bp = mp.param['band'][d] if d == bands_n: # high-end band X_wave[d], _ = librosa.load( args.input, bp['sr'], False, dtype=np.float32, res_type=bp['res_type']) if X_wave[d].ndim == 1: X_wave[d] = np.asarray([X_wave[d], X_wave[d]]) else: # lower bands X_wave[d] = librosa.resample(X_wave[d+1], mp.param['band'][d+1]['sr'], bp['sr'], res_type=bp['res_type']) X_spec_s[d] = spec_utils.wave_to_spectrogram_mt(X_wave[d], bp['hl'], bp['n_fft'], mp.param['mid_side'], mp.param['reverse']) if d == bands_n and args.high_end_process in ['bypass', 'correlation']: input_high_end_h = (bp['n_fft']//2 - bp['crop_stop']) + (mp.param['pre_filter_stop'] - mp.param['pre_filter_start']) input_high_end = X_spec_s[d][:, bp['n_fft']//2-input_high_end_h:bp['n_fft']//2, :] X_spec_m = spec_utils.combine_spectrograms(X_spec_s, mp) del X_wave, X_spec_s print('done') vr = VocalRemover(model, device, args.window_size) if args.tta: pred, X_mag, X_phase = vr.inference_tta(X_spec_m, {'value': args.aggressiveness, 'split_bin': mp.param['band'][1]['crop_stop']}) else: pred, X_mag, X_phase = vr.inference(X_spec_m, {'value': args.aggressiveness, 'split_bin': mp.param['band'][1]['crop_stop']}) if args.postprocess: print('post processing...', end=' ') pred_inv = np.clip(X_mag - pred, 0, np.inf) pred = spec_utils.mask_silence(pred, pred_inv) print('done') if 'is_vocal_model' in mp.param: # swap stems = {'inst': 'Vocals', 'vocals': 'Instruments'} else: stems = {'inst': 'Instruments', 'vocals': 'Vocals'} print('inverse stft of {}...'.format(stems['inst']), end=' ') y_spec_m = pred * X_phase v_spec_m = X_spec_m - y_spec_m if args.high_end_process == 'bypass': wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp, input_high_end_h, input_high_end) elif args.high_end_process == 'correlation': for i in range(input_high_end.shape[2]): for c in range(2): X_mag_max = np.amax(input_high_end[c, :, i]) b1 = mp.param['pre_filter_start']-input_high_end_h//2 b2 = mp.param['pre_filter_start']-1 if X_mag_max > 0 and np.sum(np.abs(v_spec_m[c, b1:b2, i])) / (b2 - b1) > 0.07: y_mag = np.median(y_spec_m[c, b1:b2, i]) input_high_end[c, :, i] = np.true_divide(input_high_end[c, :, i], abs(X_mag_max) / min(abs(y_mag * 4), abs(X_mag_max))) wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp, input_high_end_h, input_high_end) else: wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp) print('done') model_name = os.path.splitext(os.path.basename(args.pretrained_modelA))[0] sf.write(os.path.join('ensembled/temp', '1_{}_{}.wav'.format(model_name, stems['inst'])), wave, mp.param['sr']) if True: print('inverse stft of {}...'.format(stems['vocals']), end=' ') #v_spec_m = X_spec_m - y_spec_m wave = spec_utils.cmb_spectrogram_to_wave(v_spec_m, mp) print('done') sf.write(os.path.join('ensembled/temp', '1_{}_{}.wav'.format(model_name, stems['vocals'])), wave, mp.param['sr']) if args.output_image: with open('{}_{}.jpg'.format(basename, stems['inst']), mode='wb') as f: image = spec_utils.spectrogram_to_image(y_spec_m) _, bin_image = cv2.imencode('.jpg', image) bin_image.tofile(f) with open('{}_{}.jpg'.format(basename, stems['vocals']), mode='wb') as f: image = spec_utils.spectrogram_to_image(v_spec_m) _, bin_image = cv2.imencode('.jpg', image) bin_image.tofile(f) print('Total time: {0:.{1}f}s'.format(time.time() - start_time, 1)) ####################################################-INERATION2-#################################################### if args.nn_architecture == 'default': from lib import nets #if '' == args.model_params: # mp = ModelParameters(args.pretrained_model) #else: mp = ModelParameters(args.model_params) start_time = time.time() print('loading MGM-v5-4Band-44100-BETA2...', end=' ') device = torch.device('cpu') model = nets.CascadedASPPNet(mp.param['bins'] * 2) model.load_state_dict(torch.load(args.pretrained_modelB, map_location=device)) if torch.cuda.is_available() and args.gpu >= 0: device = torch.device('cuda:{}'.format(args.gpu)) model.to(device) print('done') print('loading & stft of wave source...', end=' ') X_wave, y_wave, X_spec_s, y_spec_s = {}, {}, {}, {} basename = os.path.splitext(os.path.basename(args.input))[0] bands_n = len(mp.param['band']) for d in range(bands_n, 0, -1): bp = mp.param['band'][d] if d == bands_n: # high-end band X_wave[d], _ = librosa.load( args.input, bp['sr'], False, dtype=np.float32, res_type=bp['res_type']) if X_wave[d].ndim == 1: X_wave[d] = np.asarray([X_wave[d], X_wave[d]]) else: # lower bands X_wave[d] = librosa.resample(X_wave[d+1], mp.param['band'][d+1]['sr'], bp['sr'], res_type=bp['res_type']) X_spec_s[d] = spec_utils.wave_to_spectrogram_mt(X_wave[d], bp['hl'], bp['n_fft'], mp.param['mid_side'], mp.param['reverse']) if d == bands_n and args.high_end_process in ['bypass', 'correlation']: input_high_end_h = (bp['n_fft']//2 - bp['crop_stop']) + (mp.param['pre_filter_stop'] - mp.param['pre_filter_start']) input_high_end = X_spec_s[d][:, bp['n_fft']//2-input_high_end_h:bp['n_fft']//2, :] X_spec_m = spec_utils.combine_spectrograms(X_spec_s, mp) del X_wave, X_spec_s print('done') vr = VocalRemover(model, device, args.window_size) if args.tta: pred, X_mag, X_phase = vr.inference_tta(X_spec_m, {'value': args.aggressiveness, 'split_bin': mp.param['band'][1]['crop_stop']}) else: pred, X_mag, X_phase = vr.inference(X_spec_m, {'value': args.aggressiveness, 'split_bin': mp.param['band'][1]['crop_stop']}) if args.postprocess: print('post processing...', end=' ') pred_inv = np.clip(X_mag - pred, 0, np.inf) pred = spec_utils.mask_silence(pred, pred_inv) print('done') if 'is_vocal_model' in mp.param: # swap stems = {'inst': 'Vocals', 'vocals': 'Instruments'} else: stems = {'inst': 'Instruments', 'vocals': 'Vocals'} print('inverse stft of {}...'.format(stems['inst']), end=' ') y_spec_m = pred * X_phase v_spec_m = X_spec_m - y_spec_m if args.high_end_process == 'bypass': wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp, input_high_end_h, input_high_end) elif args.high_end_process == 'correlation': for i in range(input_high_end.shape[2]): for c in range(2): X_mag_max = np.amax(input_high_end[c, :, i]) b1 = mp.param['pre_filter_start']-input_high_end_h//2 b2 = mp.param['pre_filter_start']-1 if X_mag_max > 0 and np.sum(np.abs(v_spec_m[c, b1:b2, i])) / (b2 - b1) > 0.07: y_mag = np.median(y_spec_m[c, b1:b2, i]) input_high_end[c, :, i] = np.true_divide(input_high_end[c, :, i], abs(X_mag_max) / min(abs(y_mag * 4), abs(X_mag_max))) wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp, input_high_end_h, input_high_end) else: wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp) print('done') model_name = os.path.splitext(os.path.basename(args.pretrained_modelB))[0] sf.write(os.path.join('ensembled/temp', '2_{}_{}.wav'.format(model_name, stems['inst'])), wave, mp.param['sr']) if True: print('inverse stft of {}...'.format(stems['vocals']), end=' ') #v_spec_m = X_spec_m - y_spec_m wave = spec_utils.cmb_spectrogram_to_wave(v_spec_m, mp) print('done') sf.write(os.path.join('ensembled/temp', '2_{}_{}.wav'.format(model_name, stems['vocals'])), wave, mp.param['sr']) if args.output_image: with open('{}_{}.jpg'.format(basename, stems['inst']), mode='wb') as f: image = spec_utils.spectrogram_to_image(y_spec_m) _, bin_image = cv2.imencode('.jpg', image) bin_image.tofile(f) with open('{}_{}.jpg'.format(basename, stems['vocals']), mode='wb') as f: image = spec_utils.spectrogram_to_image(v_spec_m) _, bin_image = cv2.imencode('.jpg', image) bin_image.tofile(f) print('Total time: {0:.{1}f}s'.format(time.time() - start_time, 1)) ####################################################-INERATION3-#################################################### if args.nn_architectureA == '123821KB': from lib import nets_123821KB as nets #if '' == args.model_params: # mp = ModelParameters(args.pretrained_model) #else: mp = ModelParameters(args.model_params) start_time = time.time() print('loading HighPrecison_4band_1...', end=' ') device = torch.device('cpu') model = nets.CascadedASPPNet(mp.param['bins'] * 2) model.load_state_dict(torch.load(args.pretrained_modelC, map_location=device)) if torch.cuda.is_available() and args.gpu >= 0: device = torch.device('cuda:{}'.format(args.gpu)) model.to(device) print('done') print('loading & stft of wave source...', end=' ') X_wave, y_wave, X_spec_s, y_spec_s = {}, {}, {}, {} basename = os.path.splitext(os.path.basename(args.input))[0] bands_n = len(mp.param['band']) for d in range(bands_n, 0, -1): bp = mp.param['band'][d] if d == bands_n: # high-end band X_wave[d], _ = librosa.load( args.input, bp['sr'], False, dtype=np.float32, res_type=bp['res_type']) if X_wave[d].ndim == 1: X_wave[d] = np.asarray([X_wave[d], X_wave[d]]) else: # lower bands X_wave[d] = librosa.resample(X_wave[d+1], mp.param['band'][d+1]['sr'], bp['sr'], res_type=bp['res_type']) X_spec_s[d] = spec_utils.wave_to_spectrogram_mt(X_wave[d], bp['hl'], bp['n_fft'], mp.param['mid_side'], mp.param['reverse']) if d == bands_n and args.high_end_process in ['bypass', 'correlation']: input_high_end_h = (bp['n_fft']//2 - bp['crop_stop']) + (mp.param['pre_filter_stop'] - mp.param['pre_filter_start']) input_high_end = X_spec_s[d][:, bp['n_fft']//2-input_high_end_h:bp['n_fft']//2, :] X_spec_m = spec_utils.combine_spectrograms(X_spec_s, mp) del X_wave, X_spec_s print('done') vr = VocalRemover(model, device, args.window_size) if args.tta: pred, X_mag, X_phase = vr.inference_tta(X_spec_m, {'value': args.aggressiveness, 'split_bin': mp.param['band'][1]['crop_stop']}) else: pred, X_mag, X_phase = vr.inference(X_spec_m, {'value': args.aggressiveness, 'split_bin': mp.param['band'][1]['crop_stop']}) if args.postprocess: print('post processing...', end=' ') pred_inv = np.clip(X_mag - pred, 0, np.inf) pred = spec_utils.mask_silence(pred, pred_inv) print('done') if 'is_vocal_model' in mp.param: # swap stems = {'inst': 'Vocals', 'vocals': 'Instruments'} else: stems = {'inst': 'Instruments', 'vocals': 'Vocals'} print('inverse stft of {}...'.format(stems['inst']), end=' ') y_spec_m = pred * X_phase v_spec_m = X_spec_m - y_spec_m if args.high_end_process == 'bypass': wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp, input_high_end_h, input_high_end) elif args.high_end_process == 'correlation': for i in range(input_high_end.shape[2]): for c in range(2): X_mag_max = np.amax(input_high_end[c, :, i]) b1 = mp.param['pre_filter_start']-input_high_end_h//2 b2 = mp.param['pre_filter_start']-1 if X_mag_max > 0 and np.sum(np.abs(v_spec_m[c, b1:b2, i])) / (b2 - b1) > 0.07: y_mag = np.median(y_spec_m[c, b1:b2, i]) input_high_end[c, :, i] = np.true_divide(input_high_end[c, :, i], abs(X_mag_max) / min(abs(y_mag * 4), abs(X_mag_max))) wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp, input_high_end_h, input_high_end) else: wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp) print('done') model_name = os.path.splitext(os.path.basename(args.pretrained_modelC))[0] sf.write(os.path.join('ensembled/temp', '3_{}_{}.wav'.format(model_name, stems['inst'])), wave, mp.param['sr']) if True: print('inverse stft of {}...'.format(stems['vocals']), end=' ') #v_spec_m = X_spec_m - y_spec_m wave = spec_utils.cmb_spectrogram_to_wave(v_spec_m, mp) print('done') sf.write(os.path.join('ensembled/temp', '3_{}_{}.wav'.format(model_name, stems['vocals'])), wave, mp.param['sr']) if args.output_image: with open('{}_{}.jpg'.format(basename, stems['inst']), mode='wb') as f: image = spec_utils.spectrogram_to_image(y_spec_m) _, bin_image = cv2.imencode('.jpg', image) bin_image.tofile(f) with open('{}_{}.jpg'.format(basename, stems['vocals']), mode='wb') as f: image = spec_utils.spectrogram_to_image(v_spec_m) _, bin_image = cv2.imencode('.jpg', image) bin_image.tofile(f) print('Total time: {0:.{1}f}s'.format(time.time() - start_time, 1)) ####################################################-INERATION4-#################################################### if args.nn_architectureA == '123821KB': from lib import nets_123821KB as nets #if '' == args.model_params: # mp = ModelParameters(args.pretrained_model) #else: mp = ModelParameters(args.model_params) start_time = time.time() print('loading HighPrecison_4band_2...', end=' ') device = torch.device('cpu') model = nets.CascadedASPPNet(mp.param['bins'] * 2) model.load_state_dict(torch.load(args.pretrained_modelD, map_location=device)) if torch.cuda.is_available() and args.gpu >= 0: device = torch.device('cuda:{}'.format(args.gpu)) model.to(device) print('done') print('loading & stft of wave source...', end=' ') X_wave, y_wave, X_spec_s, y_spec_s = {}, {}, {}, {} basename = os.path.splitext(os.path.basename(args.input))[0] bands_n = len(mp.param['band']) for d in range(bands_n, 0, -1): bp = mp.param['band'][d] if d == bands_n: # high-end band X_wave[d], _ = librosa.load( args.input, bp['sr'], False, dtype=np.float32, res_type=bp['res_type']) if X_wave[d].ndim == 1: X_wave[d] = np.asarray([X_wave[d], X_wave[d]]) else: # lower bands X_wave[d] = librosa.resample(X_wave[d+1], mp.param['band'][d+1]['sr'], bp['sr'], res_type=bp['res_type']) X_spec_s[d] = spec_utils.wave_to_spectrogram_mt(X_wave[d], bp['hl'], bp['n_fft'], mp.param['mid_side'], mp.param['reverse']) if d == bands_n and args.high_end_process in ['bypass', 'correlation']: input_high_end_h = (bp['n_fft']//2 - bp['crop_stop']) + (mp.param['pre_filter_stop'] - mp.param['pre_filter_start']) input_high_end = X_spec_s[d][:, bp['n_fft']//2-input_high_end_h:bp['n_fft']//2, :] X_spec_m = spec_utils.combine_spectrograms(X_spec_s, mp) del X_wave, X_spec_s print('done') vr = VocalRemover(model, device, args.window_size) if args.tta: pred, X_mag, X_phase = vr.inference_tta(X_spec_m, {'value': args.aggressiveness, 'split_bin': mp.param['band'][1]['crop_stop']}) else: pred, X_mag, X_phase = vr.inference(X_spec_m, {'value': args.aggressiveness, 'split_bin': mp.param['band'][1]['crop_stop']}) if args.postprocess: print('post processing...', end=' ') pred_inv = np.clip(X_mag - pred, 0, np.inf) pred = spec_utils.mask_silence(pred, pred_inv) print('done') if 'is_vocal_model' in mp.param: # swap stems = {'inst': 'Vocals', 'vocals': 'Instruments'} else: stems = {'inst': 'Instruments', 'vocals': 'Vocals'} print('inverse stft of {}...'.format(stems['inst']), end=' ') y_spec_m = pred * X_phase v_spec_m = X_spec_m - y_spec_m if args.high_end_process == 'bypass': wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp, input_high_end_h, input_high_end) elif args.high_end_process == 'correlation': for i in range(input_high_end.shape[2]): for c in range(2): X_mag_max = np.amax(input_high_end[c, :, i]) b1 = mp.param['pre_filter_start']-input_high_end_h//2 b2 = mp.param['pre_filter_start']-1 if X_mag_max > 0 and np.sum(np.abs(v_spec_m[c, b1:b2, i])) / (b2 - b1) > 0.07: y_mag = np.median(y_spec_m[c, b1:b2, i]) input_high_end[c, :, i] = np.true_divide(input_high_end[c, :, i], abs(X_mag_max) / min(abs(y_mag * 4), abs(X_mag_max))) wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp, input_high_end_h, input_high_end) else: wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp) print('done') model_name = os.path.splitext(os.path.basename(args.pretrained_modelD))[0] sf.write(os.path.join('ensembled/temp', '4_{}_{}.wav'.format(model_name, stems['inst'])), wave, mp.param['sr']) if True: print('inverse stft of {}...'.format(stems['vocals']), end=' ') #v_spec_m = X_spec_m - y_spec_m wave = spec_utils.cmb_spectrogram_to_wave(v_spec_m, mp) print('done') sf.write(os.path.join('ensembled/temp', '4_{}_{}.wav'.format(model_name, stems['vocals'])), wave, mp.param['sr']) if args.output_image: with open('{}_{}.jpg'.format(basename, stems['inst']), mode='wb') as f: image = spec_utils.spectrogram_to_image(y_spec_m) _, bin_image = cv2.imencode('.jpg', image) bin_image.tofile(f) with open('{}_{}.jpg'.format(basename, stems['vocals']), mode='wb') as f: image = spec_utils.spectrogram_to_image(v_spec_m) _, bin_image = cv2.imencode('.jpg', image) bin_image.tofile(f) print('Total time: {0:.{1}f}s'.format(time.time() - start_time, 1)) ####################################################-INERATION5-#################################################### if args.nn_architectureB == '129605KB': from lib import nets_129605KB as nets #if '' == args.model_params: # mp = ModelParameters(args.pretrained_model) #else: mp = ModelParameters(args.model_params) start_time = time.time() print('loading NewLayer_4band_1...', end=' ') device = torch.device('cpu') model = nets.CascadedASPPNet(mp.param['bins'] * 2) model.load_state_dict(torch.load(args.pretrained_modelE, map_location=device)) if torch.cuda.is_available() and args.gpu >= 0: device = torch.device('cuda:{}'.format(args.gpu)) model.to(device) print('done') print('loading & stft of wave source...', end=' ') X_wave, y_wave, X_spec_s, y_spec_s = {}, {}, {}, {} basename = os.path.splitext(os.path.basename(args.input))[0] bands_n = len(mp.param['band']) for d in range(bands_n, 0, -1): bp = mp.param['band'][d] if d == bands_n: # high-end band X_wave[d], _ = librosa.load( args.input, bp['sr'], False, dtype=np.float32, res_type=bp['res_type']) if X_wave[d].ndim == 1: X_wave[d] = np.asarray([X_wave[d], X_wave[d]]) else: # lower bands X_wave[d] = librosa.resample(X_wave[d+1], mp.param['band'][d+1]['sr'], bp['sr'], res_type=bp['res_type']) X_spec_s[d] = spec_utils.wave_to_spectrogram_mt(X_wave[d], bp['hl'], bp['n_fft'], mp.param['mid_side'], mp.param['reverse']) if d == bands_n and args.high_end_process in ['bypass', 'correlation']: input_high_end_h = (bp['n_fft']//2 - bp['crop_stop']) + (mp.param['pre_filter_stop'] - mp.param['pre_filter_start']) input_high_end = X_spec_s[d][:, bp['n_fft']//2-input_high_end_h:bp['n_fft']//2, :] X_spec_m = spec_utils.combine_spectrograms(X_spec_s, mp) del X_wave, X_spec_s print('done') vr = VocalRemover(model, device, max(args.window_size,320)) if args.tta: pred, X_mag, X_phase = vr.inference_tta(X_spec_m, {'value': args.aggressiveness, 'split_bin': mp.param['band'][1]['crop_stop']}) else: pred, X_mag, X_phase = vr.inference(X_spec_m, {'value': args.aggressiveness, 'split_bin': mp.param['band'][1]['crop_stop']}) if args.postprocess: print('post processing...', end=' ') pred_inv = np.clip(X_mag - pred, 0, np.inf) pred = spec_utils.mask_silence(pred, pred_inv) print('done') if 'is_vocal_model' in mp.param: # swap stems = {'inst': 'Vocals', 'vocals': 'Instruments'} else: stems = {'inst': 'Instruments', 'vocals': 'Vocals'} print('inverse stft of {}...'.format(stems['inst']), end=' ') y_spec_m = pred * X_phase v_spec_m = X_spec_m - y_spec_m if args.high_end_process == 'bypass': wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp, input_high_end_h, input_high_end) elif args.high_end_process == 'correlation': for i in range(input_high_end.shape[2]): for c in range(2): X_mag_max = np.amax(input_high_end[c, :, i]) b1 = mp.param['pre_filter_start']-input_high_end_h//2 b2 = mp.param['pre_filter_start']-1 if X_mag_max > 0 and np.sum(np.abs(v_spec_m[c, b1:b2, i])) / (b2 - b1) > 0.07: y_mag = np.median(y_spec_m[c, b1:b2, i]) input_high_end[c, :, i] = np.true_divide(input_high_end[c, :, i], abs(X_mag_max) / min(abs(y_mag * 4), abs(X_mag_max))) wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp, input_high_end_h, input_high_end) else: wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp) print('done') model_name = os.path.splitext(os.path.basename(args.pretrained_modelE))[0] sf.write(os.path.join('ensembled/temp', '5_{}_{}.wav'.format(model_name, stems['inst'])), wave, mp.param['sr']) if True: print('inverse stft of {}...'.format(stems['vocals']), end=' ') #v_spec_m = X_spec_m - y_spec_m wave = spec_utils.cmb_spectrogram_to_wave(v_spec_m, mp) print('done') sf.write(os.path.join('ensembled/temp', '5_{}_{}.wav'.format(model_name, stems['vocals'])), wave, mp.param['sr']) if args.output_image: with open('{}_{}.jpg'.format(basename, stems['inst']), mode='wb') as f: image = spec_utils.spectrogram_to_image(y_spec_m) _, bin_image = cv2.imencode('.jpg', image) bin_image.tofile(f) with open('{}_{}.jpg'.format(basename, stems['vocals']), mode='wb') as f: image = spec_utils.spectrogram_to_image(v_spec_m) _, bin_image = cv2.imencode('.jpg', image) bin_image.tofile(f) print('Total time: {0:.{1}f}s'.format(time.time() - start_time, 1)) ####################################################-INERATION6-#################################################### if args.nn_architectureB == '129605KB': from lib import nets_129605KB as nets #if '' == args.model_params: # mp = ModelParameters(args.pretrained_model) #else: mp = ModelParameters(args.model_params) start_time = time.time() print('loading NewLayer_4band_2...', end=' ') device = torch.device('cpu') model = nets.CascadedASPPNet(mp.param['bins'] * 2) model.load_state_dict(torch.load(args.pretrained_modelF, map_location=device)) if torch.cuda.is_available() and args.gpu >= 0: device = torch.device('cuda:{}'.format(args.gpu)) model.to(device) print('done') print('loading & stft of wave source...', end=' ') X_wave, y_wave, X_spec_s, y_spec_s = {}, {}, {}, {} basename = os.path.splitext(os.path.basename(args.input))[0] bands_n = len(mp.param['band']) for d in range(bands_n, 0, -1): bp = mp.param['band'][d] if d == bands_n: # high-end band X_wave[d], _ = librosa.load( args.input, bp['sr'], False, dtype=np.float32, res_type=bp['res_type']) if X_wave[d].ndim == 1: X_wave[d] = np.asarray([X_wave[d], X_wave[d]]) else: # lower bands X_wave[d] = librosa.resample(X_wave[d+1], mp.param['band'][d+1]['sr'], bp['sr'], res_type=bp['res_type']) X_spec_s[d] = spec_utils.wave_to_spectrogram_mt(X_wave[d], bp['hl'], bp['n_fft'], mp.param['mid_side'], mp.param['reverse']) if d == bands_n and args.high_end_process in ['bypass', 'correlation']: input_high_end_h = (bp['n_fft']//2 - bp['crop_stop']) + (mp.param['pre_filter_stop'] - mp.param['pre_filter_start']) input_high_end = X_spec_s[d][:, bp['n_fft']//2-input_high_end_h:bp['n_fft']//2, :] X_spec_m = spec_utils.combine_spectrograms(X_spec_s, mp) del X_wave, X_spec_s print('done') vr = VocalRemover(model, device, max(args.window_size,320)) if args.tta: pred, X_mag, X_phase = vr.inference_tta(X_spec_m, {'value': args.aggressiveness, 'split_bin': mp.param['band'][1]['crop_stop']}) else: pred, X_mag, X_phase = vr.inference(X_spec_m, {'value': args.aggressiveness, 'split_bin': mp.param['band'][1]['crop_stop']}) if args.postprocess: print('post processing...', end=' ') pred_inv = np.clip(X_mag - pred, 0, np.inf) pred = spec_utils.mask_silence(pred, pred_inv) print('done') if 'is_vocal_model' in mp.param: # swap stems = {'inst': 'Vocals', 'vocals': 'Instruments'} else: stems = {'inst': 'Instruments', 'vocals': 'Vocals'} print('inverse stft of {}...'.format(stems['inst']), end=' ') y_spec_m = pred * X_phase v_spec_m = X_spec_m - y_spec_m if args.high_end_process == 'bypass': wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp, input_high_end_h, input_high_end) elif args.high_end_process == 'correlation': for i in range(input_high_end.shape[2]): for c in range(2): X_mag_max = np.amax(input_high_end[c, :, i]) b1 = mp.param['pre_filter_start']-input_high_end_h//2 b2 = mp.param['pre_filter_start']-1 if X_mag_max > 0 and np.sum(np.abs(v_spec_m[c, b1:b2, i])) / (b2 - b1) > 0.07: y_mag = np.median(y_spec_m[c, b1:b2, i]) input_high_end[c, :, i] = np.true_divide(input_high_end[c, :, i], abs(X_mag_max) / min(abs(y_mag * 4), abs(X_mag_max))) wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp, input_high_end_h, input_high_end) else: wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp) print('done') model_name = os.path.splitext(os.path.basename(args.pretrained_modelF))[0] sf.write(os.path.join('ensembled/temp', '6_{}_{}.wav'.format(model_name, stems['inst'])), wave, mp.param['sr']) if True: print('inverse stft of {}...'.format(stems['vocals']), end=' ') #v_spec_m = X_spec_m - y_spec_m wave = spec_utils.cmb_spectrogram_to_wave(v_spec_m, mp) print('done') sf.write(os.path.join('ensembled/temp', '6_{}_{}.wav'.format(model_name, stems['vocals'])), wave, mp.param['sr']) if args.output_image: with open('{}_{}.jpg'.format(basename, stems['inst']), mode='wb') as f: image = spec_utils.spectrogram_to_image(y_spec_m) _, bin_image = cv2.imencode('.jpg', image) bin_image.tofile(f) with open('{}_{}.jpg'.format(basename, stems['vocals']), mode='wb') as f: image = spec_utils.spectrogram_to_image(v_spec_m) _, bin_image = cv2.imencode('.jpg', image) bin_image.tofile(f) print('Total time: {0:.{1}f}s'.format(time.time() - start_time, 1)) ####################################################-INERATION7-#################################################### if args.nn_architectureB == '129605KB': from lib import nets_129605KB as nets #if '' == args.model_params: # mp = ModelParameters(args.pretrained_model) #else: mp = ModelParameters(args.model_params) start_time = time.time() print('loading NewLayer_4band_3...', end=' ') device = torch.device('cpu') model = nets.CascadedASPPNet(mp.param['bins'] * 2) model.load_state_dict(torch.load(args.pretrained_modelG, map_location=device)) if torch.cuda.is_available() and args.gpu >= 0: device = torch.device('cuda:{}'.format(args.gpu)) model.to(device) print('done') print('loading & stft of wave source...', end=' ') X_wave, y_wave, X_spec_s, y_spec_s = {}, {}, {}, {} basename = os.path.splitext(os.path.basename(args.input))[0] bands_n = len(mp.param['band']) for d in range(bands_n, 0, -1): bp = mp.param['band'][d] if d == bands_n: # high-end band X_wave[d], _ = librosa.load( args.input, bp['sr'], False, dtype=np.float32, res_type=bp['res_type']) if X_wave[d].ndim == 1: X_wave[d] = np.asarray([X_wave[d], X_wave[d]]) else: # lower bands X_wave[d] = librosa.resample(X_wave[d+1], mp.param['band'][d+1]['sr'], bp['sr'], res_type=bp['res_type']) X_spec_s[d] = spec_utils.wave_to_spectrogram_mt(X_wave[d], bp['hl'], bp['n_fft'], mp.param['mid_side'], mp.param['reverse']) if d == bands_n and args.high_end_process in ['bypass', 'correlation']: input_high_end_h = (bp['n_fft']//2 - bp['crop_stop']) + (mp.param['pre_filter_stop'] - mp.param['pre_filter_start']) input_high_end = X_spec_s[d][:, bp['n_fft']//2-input_high_end_h:bp['n_fft']//2, :] X_spec_m = spec_utils.combine_spectrograms(X_spec_s, mp) del X_wave, X_spec_s print('done') vr = VocalRemover(model, device, max(args.window_size,320)) if args.tta: pred, X_mag, X_phase = vr.inference_tta(X_spec_m, {'value': args.aggressiveness, 'split_bin': mp.param['band'][1]['crop_stop']}) else: pred, X_mag, X_phase = vr.inference(X_spec_m, {'value': args.aggressiveness, 'split_bin': mp.param['band'][1]['crop_stop']}) if args.postprocess: print('post processing...', end=' ') pred_inv = np.clip(X_mag - pred, 0, np.inf) pred = spec_utils.mask_silence(pred, pred_inv) print('done') if 'is_vocal_model' in mp.param: # swap stems = {'inst': 'Vocals', 'vocals': 'Instruments'} else: stems = {'inst': 'Instruments', 'vocals': 'Vocals'} print('inverse stft of {}...'.format(stems['inst']), end=' ') y_spec_m = pred * X_phase v_spec_m = X_spec_m - y_spec_m if args.high_end_process == 'bypass': wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp, input_high_end_h, input_high_end) elif args.high_end_process == 'correlation': for i in range(input_high_end.shape[2]): for c in range(2): X_mag_max = np.amax(input_high_end[c, :, i]) b1 = mp.param['pre_filter_start']-input_high_end_h//2 b2 = mp.param['pre_filter_start']-1 if X_mag_max > 0 and np.sum(np.abs(v_spec_m[c, b1:b2, i])) / (b2 - b1) > 0.07: y_mag = np.median(y_spec_m[c, b1:b2, i]) input_high_end[c, :, i] = np.true_divide(input_high_end[c, :, i], abs(X_mag_max) / min(abs(y_mag * 4), abs(X_mag_max))) wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp, input_high_end_h, input_high_end) else: wave = spec_utils.cmb_spectrogram_to_wave(y_spec_m, mp) print('done') model_name = os.path.splitext(os.path.basename(args.pretrained_modelG))[0] sf.write(os.path.join('ensembled/temp', '7_{}_{}.wav'.format(model_name, stems['inst'])), wave, mp.param['sr']) if True: print('inverse stft of {}...'.format(stems['vocals']), end=' ') #v_spec_m = X_spec_m - y_spec_m wave = spec_utils.cmb_spectrogram_to_wave(v_spec_m, mp) print('done') sf.write(os.path.join('ensembled/temp', '7_{}_{}.wav'.format(model_name, stems['vocals'])), wave, mp.param['sr']) if args.output_image: with open('{}_{}.jpg'.format(basename, stems['inst']), mode='wb') as f: image = spec_utils.spectrogram_to_image(y_spec_m) _, bin_image = cv2.imencode('.jpg', image) bin_image.tofile(f) with open('{}_{}.jpg'.format(basename, stems['vocals']), mode='wb') as f: image = spec_utils.spectrogram_to_image(v_spec_m) _, bin_image = cv2.imencode('.jpg', image) bin_image.tofile(f) print('Total time: {0:.{1}f}s'.format(time.time() - start_time, 1)) ####################################################^INERATIONS-COMPLETE^#################################################### ####################################################-ENSEMBLING-BEGIN-####################################################### if args.deepextraction: print('Ensembling Instrumentals...') os.system("python lib/spec_utils.py -a min_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/1_MGM-v5-4Band-44100-BETA1_Instruments.wav ensembled/temp/2_MGM-v5-4Band-44100-BETA2_Instruments.wav -o ensembled/temp/1E2E_ensam1") os.system("python lib/spec_utils.py -a min_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/3_HighPrecison_4band_1_Instruments.wav ensembled/temp/4_HighPrecison_4band_2_Instruments.wav -o ensembled/temp/3E4E_ensam1") os.system("python lib/spec_utils.py -a min_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/5_NewLayer_4band_1_Instruments.wav ensembled/temp/6_NewLayer_4band_2_Instruments.wav -o ensembled/temp/5E6E_ensam3") os.system("python lib/spec_utils.py -a min_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/1E2E_ensam1_v.wav ensembled/temp/3E4E_ensam1_v.wav -o ensembled/temp/1E2E3E4E_ensam4") os.system("python lib/spec_utils.py -a min_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/1E2E3E4E_ensam4_v.wav ensembled/temp/5E6E_ensam3_v.wav -o ensembled/temp/A6_ensam5") os.system("python lib/spec_utils.py -a min_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/7_NewLayer_4band_3_Instruments.wav ensembled/temp/A6_ensam5_v.wav -o ensembled/temp/Complete") print('Ensembling Vocals...') os.system("python lib/spec_utils.py -a max_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/1_MGM-v5-4Band-44100-BETA1_Vocals.wav ensembled/temp/2_MGM-v5-4Band-44100-BETA2_Vocals.wav -o ensembled/temp/1E2EV_ensam1") os.system("python lib/spec_utils.py -a max_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/3_HighPrecison_4band_1_Vocals.wav ensembled/temp/4_HighPrecison_4band_2_Vocals.wav -o ensembled/temp/3E4EV_ensam1") os.system("python lib/spec_utils.py -a max_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/5_NewLayer_4band_1_Vocals.wav ensembled/temp/6_NewLayer_4band_2_Vocals.wav -o ensembled/temp/5E6EV_ensam3") os.system("python lib/spec_utils.py -a max_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/1E2EV_ensam1_v.wav ensembled/temp/3E4EV_ensam1_v.wav -o ensembled/temp/1E2E3E4EV_ensam4") os.system("python lib/spec_utils.py -a max_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/1E2E3E4EV_ensam4_v.wav ensembled/temp/5E6EV_ensam3_v.wav -o ensembled/temp/A6V_ensam5") os.system("python lib/spec_utils.py -a max_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/7_NewLayer_4band_3_Vocals.wav ensembled/temp/A6V_ensam5_v.wav -o ensembled/temp/CompleteV") print('Performing Deep Extraction...') os.system("python lib/spec_utils.py -a min_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/Complete_v.wav ensembled/temp/CompleteV_v.wav -o ensembled/temp/difftemp") os.system("python lib/spec_utils.py -a invert -v -m modelparams/1band_sr44100_hl512.json ensembled/temp/Complete_v.wav ensembled/temp/difftemp_v.wav -o ensembled/temp/difftempC") os.rename('ensembled/temp/difftempC_v.wav', 'ensembled/{}_4BAND_Ensembled_DeepExtraction_Instrumental.wav'.format(basename)) os.rename('ensembled/temp/Complete_v.wav', 'ensembled/{}_4BAND_Ensembled_Instrumental.wav'.format(basename)) os.rename('ensembled/temp/CompleteV_v.wav', 'ensembled/{}_4BAND_Ensembled_Vocals.wav'.format(basename)) print('Deep Extraction Complete!') else: print('Ensembling Instrumentals...') os.system("python lib/spec_utils.py -a min_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/1_MGM-v5-4Band-44100-BETA1_Instruments.wav ensembled/temp/2_MGM-v5-4Band-44100-BETA2_Instruments.wav -o ensembled/temp/1E2E_ensam1") os.system("python lib/spec_utils.py -a min_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/3_HighPrecison_4band_1_Instruments.wav ensembled/temp/4_HighPrecison_4band_2_Instruments.wav -o ensembled/temp/3E4E_ensam1") os.system("python lib/spec_utils.py -a min_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/5_NewLayer_4band_1_Instruments.wav ensembled/temp/6_NewLayer_4band_2_Instruments.wav -o ensembled/temp/5E6E_ensam3") os.system("python lib/spec_utils.py -a min_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/1E2E_ensam1_v.wav ensembled/temp/3E4E_ensam1_v.wav -o ensembled/temp/1E2E3E4E_ensam4") os.system("python lib/spec_utils.py -a min_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/1E2E3E4E_ensam4_v.wav ensembled/temp/5E6E_ensam3_v.wav -o ensembled/temp/A6_ensam5") os.system("python lib/spec_utils.py -a min_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/7_NewLayer_4band_3_Instruments.wav ensembled/temp/A6_ensam5_v.wav -o ensembled/temp/Complete") os.rename('ensembled/temp/Complete_v.wav', 'ensembled/{}_4BAND_Ensembled_Instrumental.wav'.format(basename)) print('Ensembling Vocals...') os.system("python lib/spec_utils.py -a max_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/1_MGM-v5-4Band-44100-BETA1_Vocals.wav ensembled/temp/2_MGM-v5-4Band-44100-BETA2_Vocals.wav -o ensembled/temp/1E2EV_ensam1") os.system("python lib/spec_utils.py -a max_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/3_HighPrecison_4band_1_Vocals.wav ensembled/temp/4_HighPrecison_4band_2_Vocals.wav -o ensembled/temp/3E4EV_ensam1") os.system("python lib/spec_utils.py -a max_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/5_NewLayer_4band_1_Vocals.wav ensembled/temp/6_NewLayer_4band_2_Vocals.wav -o ensembled/temp/5E6EV_ensam3") os.system("python lib/spec_utils.py -a max_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/1E2EV_ensam1_v.wav ensembled/temp/3E4EV_ensam1_v.wav -o ensembled/temp/1E2E3E4EV_ensam4") os.system("python lib/spec_utils.py -a max_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/1E2E3E4EV_ensam4_v.wav ensembled/temp/5E6EV_ensam3_v.wav -o ensembled/temp/A6V_ensam5") os.system("python lib/spec_utils.py -a max_mag -m modelparams/1band_sr44100_hl512.json ensembled/temp/7_NewLayer_4band_3_Vocals.wav ensembled/temp/A6V_ensam5_v.wav -o ensembled/temp/CompleteV") os.rename('ensembled/temp/CompleteV_v.wav', 'ensembled/{}_4BAND_Ensembled_Vocals.wav'.format(basename)) if args.saveindivsep: print('Saving Individual Separations...') os.rename('ensembled/temp/1_MGM-v5-4Band-44100-BETA1_Instruments.wav', 'separated/{}_MGM-v5-4Band-44100-BETA1_Instruments.wav'.format(basename)) os.rename('ensembled/temp/2_MGM-v5-4Band-44100-BETA2_Instruments.wav', 'separated/{}_MGM-v5-4Band-44100-BETA2_Instruments.wav'.format(basename)) os.rename('ensembled/temp/3_HighPrecison_4band_1_Instruments.wav', 'separated/{}_HighPrecison_4band_1_Instruments.wav'.format(basename)) os.rename('ensembled/temp/4_HighPrecison_4band_2_Instruments.wav', 'separated/{}_HighPrecison_4band_2_Instruments.wav'.format(basename)) os.rename('ensembled/temp/5_NewLayer_4band_1_Instruments.wav', 'separated/{}_NewLayer_4band_1_Instruments.wav'.format(basename)) os.rename('ensembled/temp/6_NewLayer_4band_2_Instruments.wav', 'separated/{}_NewLayer_4band_2_Instruments.wav'.format(basename)) os.rename('ensembled/temp/7_NewLayer_4band_3_Instruments.wav', 'separated/{}_NewLayer_4band_3_Instruments.wav'.format(basename)) os.rename('ensembled/temp/1_MGM-v5-4Band-44100-BETA1_Vocals.wav', 'separated/{}_MGM-v5-4Band-44100-BETA1_Vocals.wav'.format(basename)) os.rename('ensembled/temp/2_MGM-v5-4Band-44100-BETA2_Vocals.wav', 'separated/{}_MGM-v5-4Band-44100-BETA2_Vocals.wav'.format(basename)) os.rename('ensembled/temp/3_HighPrecison_4band_1_Vocals.wav', 'separated/{}_HighPrecison_4band_1_Vocals.wav'.format(basename)) os.rename('ensembled/temp/4_HighPrecison_4band_2_Vocals.wav', 'separated/{}_HighPrecison_4band_2_Vocals.wav'.format(basename)) os.rename('ensembled/temp/5_NewLayer_4band_1_Vocals.wav', 'separated/{}_NewLayer_4band_1_Vocals.wav'.format(basename)) os.rename('ensembled/temp/6_NewLayer_4band_2_Vocals.wav', 'separated/{}_NewLayer_4band_2_Vocals.wav'.format(basename)) os.rename('ensembled/temp/7_NewLayer_4band_3_Vocals.wav', 'separated/{}_NewLayer_4band_3_Vocals.wav'.format(basename)) os.remove("ensembled/temp/A6V_ensam5_v.wav") os.remove("ensembled/temp/1E2E3E4EV_ensam4_v.wav") os.remove("ensembled/temp/5E6EV_ensam3_v.wav") os.remove("ensembled/temp/3E4EV_ensam1_v.wav") os.remove("ensembled/temp/1E2EV_ensam1_v.wav") os.remove("ensembled/temp/A6_ensam5_v.wav") os.remove("ensembled/temp/1E2E3E4E_ensam4_v.wav") os.remove("ensembled/temp/5E6E_ensam3_v.wav") os.remove("ensembled/temp/3E4E_ensam1_v.wav") os.remove("ensembled/temp/1E2E_ensam1_v.wav") os.remove("ensembled/temp/difftemp_v.wav") print('All Separations Saved!') else: print('Cleaning Up...') dir = 'ensembled/temp' for file in os.scandir(dir): os.remove(file.path) print('Complete!') if __name__ == '__main__': main()